ITTO20130105A1 - SYSTEM TO DIAGNOSTICATE THE FUNCTIONING STATUS OF AN ACOUSTIC, RELATED PROCEDURE AND KIT - Google Patents

Description

"System for diagnosing the operating status of a hearing aid, related procedure and equipment"

TEXT OF THE DESCRIPTION

Field of the invention

The present invention relates to a system for diagnosing the operating state of an acoustic apparatus, comprising means for analyzing the frequency response of said acoustic apparatus.

General technical problem

Hearing aids, or apparatuses, are analog or digital medical devices that filter and amplify sound, which are used as hearing aids. The frequency response of the filter can be configured to compensate for frequency-dependent hearing loss, for example as determined based on an audiogram. For this task and to check the operating status of the hearing system, a specialized technician is required, for example the hearing aid specialist.

In particular, the operating status of a hearing aid requires initial home care by the hearing aid specialist. If home care by the hearing aid professional is not sufficient, the medical device must be brought to the authorized center for assistance.

The home care of the audio-prosthetist involves the presence of costs both in monetary terms and in terms of time borne by both the patient and the manufacturer. Home assistance or having to bring the medical device to the authorized center involves lengthening the time for technical assistance even for simple problems that can be solved directly by the user. Furthermore, today it is not possible to establish a cost estimate without first having directly viewed the product.

The present invention aims to solve the drawbacks of the known art, in particular to indicate a system for diagnosing the operating state of an acoustic apparatus, comprising means for analyzing the frequency response of said acoustic apparatus which allows to diagnose in site without requiring the on-site intervention of a hearing care professional or other specialized technician.

The object of the present invention is achieved by a system having the characteristics forming the subject of the following claims, which form an integral part of the technical teaching administered herein in relation to the invention. The invention also relates to a corresponding procedure and set of mobile terminal and measurement housing.

Brief description of the drawings

The invention will now be described with reference to the attached drawings, given purely by way of non-limiting example, in which:

- Figure 1 is a schematic diagram representing a system for diagnosing the operating status of a hearing aid according to the invention,

- Figure 2 schematically represents a detail of the system according to the invention;

- Figures 3a and 3b schematically represent flow diagrams of diagnostic procedures implemented by the system according to the invention.

Detailed description of the invention

In short, the system according to the invention to diagnose the operating status of the hearing aid performs a test through the use of a measurement housing which houses the hearing apparatus which cooperates with a mobile terminal, in particular mobile devices latest generation such as tablets or smartphones.

According to a main aspect of the invention, this mobile terminal generates the acoustic signals to operate the test, acquires corresponding amplitude or amplification values of the hearing aid measured on the basis of the signal detected by the measuring housing, calculates a test result based on at these amplitude or amplification values and transmits a message containing the test result to a remote center.

Figure 1 shows the system for diagnosing the operating status of a hearing aid according to the invention, as a whole indicated with the numerical reference 10.

12 indicates a hearing aid to be tested. Reference 11 indicates a measurement housing, i.e. a container inside which a hearing aid 12 can be inserted. This hearing aid 12 independently generally has its own microphone for acoustic waves and a receiver / loudspeaker at the output of which the acoustic waves are supplied amplified. Therefore, the hearing aid 12 can be housed inside this housing of size 11, which, for example, is supplied together with the hearing aid 12 at the time of sale. Housing 11 is presented in the form of a case with a closing lid and internal walls lined with soundproofing material, such as polyurethane foam with a layer of variable thickness from 3 mm to 2 cm to minimize acoustic losses

Inside the measurement housing 11 there are a measurement receiver 13 and a measurement microphone 14, ie devices respectively capable of emitting sounds or acoustic waves under the driving of an electrical signal and converting acoustic waves into electrical signals. The measurement receiver 13 is for example of the 32 Ohm bipolar piezoelectric type and the measurement microphone 14 is of the 832 Ohm bipolar magnetic type.

The measurement receiver 13, which operates as a loudspeaker, is placed inside the housing of measurement 11 in the upper part in the drawing, while the measurement microphone 14 is arranged in the lower part. The hearing aid 12 is acoustically connected to the measurement receiver 13 from the side of its own microphone, in the example of an in-ear hearing aid the upper part, without the aid of any specific mechanical coupling, while the receiver of the hearing aid 12 is connected to the measurement microphone 14 of the housing 11 via a silicone coupling 20, which is also shown enlarged in a dashed circle a. This silicone coupling 20 has two holes at the ends necessary for coupling on one side of the hearing aid 12 on the side of its receiver, on the other of the measuring microphone 14 placed in housing 11.

The silicone coupling 20 wraps around the hearing aid 12 and the measurement microphone 14 creating a direct channel for sound waves, minimizing any acoustic dispersion.

The measurement microphone 14 present in the housing 11 is placed at a distance from the sound waves exit hole of the hearing aid 12 which is in the range from 0.5 to 2.5 cm to minimize acoustic losses.

The housing 11 also includes a cable 16 with a special connector, or jack, output 17 that allows connection to a terminal for mobile communications, or mobile terminal 18.

The output connector 17 is for example a 4-pole audio jack, at whose terminals the following signals are available, as shown in figure 2:

- first microphone terminal signal 23

- second microphone terminal signal 24

- right signal receiver 25

- left signal receiver 26

The output connector 17 is connected to the input connector of the mobile device 18. The mobile device 18, which is, as mentioned, for example a smartphone, or a tablet, with the possibility of communication, in particular of data, on a mobile network , but it is also configured as a computer, it is therefore configured, by means of a control software, to carry out a method for diagnosing the operating state of an acoustic apparatus whose flow is represented in the flow diagrams of figures 3a and 3b.

This procedure involves carrying out a test of the hearing aid 12 by generating through the mobile phone 18 a test signal at variable frequency ST, in particular a signal that subsequently assumes a plurality of frequencies f1 ... fn over time. In particular, in this test signal ST, for example, sounds are generated at the following frequencies: 250 Hz; 500 Hz; 1000 Hz; 1500 Hz; 2000 Hz. Hereinafter, the test signal ST will be referred to in general, even if the output signal from the mobile terminal 18 is in itself an electrical signal which is then transformed by the receiver 13 into corresponding acoustic test waves TW. Similarly, the response signal SA that reaches the mobile terminal 18 corresponds to the conversion into an electrical signal of acoustic response waves RW output from the apparatus 12 and converted by the measurement microphone 14.

The ST variable frequency test signal generated will be at a determined amplitude, preferably at the maximum volume allowed by the terminal 18, ie at a maximum amplitude Amax.

The proposed diagnostic procedure comprises two phases of use.

A set-up phase is first envisaged, or initial setting 100, which is preferably performed by a technician or audio-prosthetist. To ensure access to the software module of this set-up phase 100 on the mobile terminal 18 only to authorized technicians, this module may require access via a password. In this set-up phase 100, at a step 110, the technician or hearing care professional or qualified person enters the data of the patient, i.e. of the user, and of the hearing aid 12, for example data comprising one or more of: Username , User surname, Device model, Serial number, Side (right or left), hearing care professional / technician telephone number.

Following the operation of entering the patient and apparatus data 110, an initial test 120 of the hearing aid 12 is performed. This execution of the initial test 120 requires the technician to act on the mobile terminal 18 according to a guided path, which is displayed on the screen of the mobile terminal 18, which indicates buttons to be operated in a given sequence. These buttons perform the following operations:

- generating 121 a test signal ST with a tone at maximum volume of the mobile terminal 18 at the i-th frequency relative to the specific step displayed in the test path, which provides for example, as indicated above, to generate tones at 250 Hz; 500 Hz; 1000 Hz; 1500 Hz; 2000 Hz. For example, you are asked to press button "1" of a keyboard that is displayed on the screen or it is the physical keyboard of terminal 18, which generates a tone at 250 Hz, then button "2" which generates a tone at 500 Hz, and so on;

- record 122 a value AS in dB of amplitude of the acoustic signal in relation to the maximum amplitude Amax of the test signal ST of response SA detected at the measurement microphone 14 during the emission of the frequency corresponding to step 121, in order to record the amplification given by the hearing aid 12 at that frequency. In particular, the value in dB is calculated as 20 * log10 (AS / Amax);

- record 123 at the end of the path a background noise during the NS set-up, i.e. the amplitude of the background noise in dB in the absence of emission of the ST test signal.

Operations 121-123 are performed both with hearing aid 12 on and with hearing aid 12 off.

All the amplitude values AS measured in the set-up phase d 100 at the respective frequencies f1… fn are recorded in a step 130 in a database 18a internal to the mobile terminal 18. 140 indicates the subsequent end of the set-up phase 100. Such amplitude values AS are used as reference data in a test step 200 of the hearing aid 12 described below.

Figure 3b therefore shows this step 200 of testing the hearing aid 12, preferably performed by the user of this hearing aid 12, ie the patient.

In a step 210, the mobile terminal 18 records the acoustic signal SA detected at the measurement microphone 14 following the variable frequency test signal ST generated sent by the terminal 18 to the receiver 13. The variable frequency test signal ST is the same of the frequencies of the test signal ST at the same frequencies f1… fnd of the set-up phase 100 and maximum amplitude Amax. The mobile terminal 18 records the amplitude value AT under test, in relation to the maximum amplitude Amaxe expressed in dB, of the test signal ST amplified by the hearing aid 12. Furthermore, the mobile terminal 18 records the amplitude value in dB of the noise of bottom during the NT test.

Subsequently, an analysis of the data just recorded in this test phase 200 is performed by the mobile terminal 18, by means of a comparison operation 220 with the data, i.e. the amplitude values AS during setup, entered in the database 18a at step 130.

If at a comparison check step 230 the amplitude data AT measured in the test step 200 are compatible with the amplitude data AS entered in the database 18a at step 130, the test procedure ends (indicated by step 250). If not, the mobile terminal 18 following this step 230 in a step 240 sends through the mobile telecommunications network 22, in particular the GSM or UMTS network, a message MG, for example an SMS message (Short Message System) to a remote center, or central, indicated by 19 in figure 1, where the hearing care professional or the specialized technician is located. The verification step 230 gives a negative result (i.e. test not positive), for example, in cases of failed test (according to a possible example criterion, the amplitude data AT measured in the test phase differ for one or more frequencies f1 ... fn to a greater extent than a predetermined value from the set-up AS amplitude data) or weak test (low amplification value on all frequencies, but not less than the predetermined value) or distorted test (the spectrum of the SA response signal seen as histogram at different frequencies f1… fn is distorted with respect to that of the test signal ST). This information allows to establish a damage / malfunction of the acoustic apparatus 12 receiver. Furthermore, the set-up amplitude data relating to the background noise NS is compared with the amplitude data of the background noise NT. If this difference is greater than a predetermined threshold value, this result implies a possible damage / malfunction of the hearing aid microphone 12.

For example, this MG message contains:

- the AS amplification values in dB at frequencies f1… fn, entered in the database during the setup phase 100 of the software both during the hearing aid phase 12 on and off;

- the value in dB of the background noise NS recorded during the setup phase 100;

- the amplification values in dB AT obtained at frequencies f1 ... just recorded during the test phase 200 with the hearing aid turned on

- the value in dB of the NT background noise recorded during the test phase 200;

- textual / graphic information on the malfunctioning / damaged component of the hearing system 12, receiver, microphone or amplifier.

- textual / graphic information on the current status of terminal 18 processed as follows:

drawing / text indicating the words "test OK"

"test failed" drawing / text together with advice to solve the problem, for example a hypothesis about the non-functioning component

drawing / text "weak test"

"distorted test" design / text.

For example, the terminal 18 includes in its memory a look-up table which, for certain combinations or patterns of the amplification values at the respective frequencies and possibly also including the noise values, returns a diagnosis, by means of text or drawing, on the malfunctioning component.

In this way, the technician at the remote center 19 can receive both values to be subjected to further processing and an initial diagnosis with approximate indications of both the severity of the fault and the type of fault. In other words, the mobile terminal 18 is able to provide autonomously useful data for a triage operation to the remote center, to establish which interventions to do locally and with what priority, without necessarily having to be analyzed at the remote center 19.

Therefore, the characteristics and advantages of the invention are clear from the above description.

The system according to the invention advantageously allows the reduction of home interventions by audio prosthetists.

Furthermore, the system according to the invention advantageously allows the operation of the hearing aid to be remotely tested.

In addition, the system according to the invention advantageously allows to give the user, from the remote center that receives indications from the mobile terminal, feedback on the malfunctioning component and therefore on the times / costs of assistance at the assistance center.

Furthermore, the system according to the invention advantageously allows the reduction of unnecessary travel to reach the assistance centers by users who belong in particular to the elderly population.

Naturally, the details of construction and the embodiments may be widely varied with respect to what has been described and illustrated without thereby departing from the scope of protection of the present invention, as defined in the appended claims.

The mobile terminal is in preferred embodiments a tablet or smartphone, or in any case a communication terminal, in particular of data, on a mobile network, which is also configured as a computer, in particular equipped with an operating system. Of course, the mobile terminal may also be a computer, preferably but not necessarily portable, to which communication functions on a mobile communication network are added or associated.

Claims (12)

CLAIMS 1. System for diagnosing the operating status of an acoustic apparatus (12), comprising means for analyzing the frequency response (AS, AT) of said hearing apparatus (12) to a test signal (ST), characterized in that said means for analyzing the frequency response (AS, AT) comprise a mobile telecommunications terminal (18) suitable for communicating on a mobile telecommunications network (22) and configured to generate a variable frequency test signal (ST) (f1 ... fn) and to acquire a response signal (SA) to called test signal (ST) with variable frequency (f1 ... fn), a measurement housing (11) configured to house said acoustic apparatus (12) and in bi-directional signal connection (16) with said mobile telecommunications terminal (18) and comprising a receiver (13) configured to receive said test signal (ST) from said mobile telecommunications terminal (18) on said bidirectional signal link (16) and emit corresponding acoustic waves (TW) towards said acoustic apparatus (12) housed in said measuring housing (11), a microphone (14) for detecting acoustic waves (RW) emitted correspondingly at the output of the hearing aid (12) and providing the response signal (SA) of the hearing aid (12) on said bidirectional link (16) to said terminal for mobile telecommunications (18). 2. System according to claim 1, characterized in that said mobile telecommunications terminal (18) comprises means for storing values (AS, AT) of said response signal (SA), in particular a database (18a) included in said mobile telecommunications terminal (18). System according to claim 1 or 2, characterized in that said terminal for mobile telecommunications (18) is configured to send information on the operating status of the acoustic apparatus (12) based on said values (AS, AT) of said signal response (SA) through said mobile network (22) to a remote exchange (19). 4. System according to claim 3, characterized in that said mobile telecommunications terminal (18) is configured to send data (AS, AT, NS, NT) measured on the hearing aid (12) to the remote exchange (19) via said measurement housing (11). 5. System according to claim 3 or 4, characterized by the fact that said terminal for mobile telecommunications (18) is configured to send to the remote control unit (19) a diagnosis on the faulty hearing aid component (12). System according to one of claims 3 to 5, characterized in that said terminal for mobile telecommunications (18) is configured to send to the remote exchange (19) a textual and / or graphic signaling representative of the test result. System according to one of claims 1 to 6, characterized in that said measuring housing (11) comprises means for minimizing acoustic losses, in particular a silicone coupling (20) configured to wrap at least an outlet portion of the apparatus acoustic (12). System according to one of claims 1 to 7, characterized in that said bidirectional connection (16) is obtained by means of a cable equipped with a 4-pole audio jack. Kit of mobile terminal (18) and measuring housing (11) configured to operate in the system according to one of claims 1 to 8. 10. Procedure for diagnosing the operating status of an acoustic apparatus (12), which involves analyzing the frequency response (AS, AT) of said hearing apparatus (12) with respect to an n test signal (ST), characterized by made of analyze the frequency response (AS, AT) by generating a variable frequency test signal (ST) (f1 ... fn) and acquiring a corresponding response signal (SA) via a mobile telecommunications terminal (18) suitable for communicating on a mobile telecommunications network (22), sending said test signal (ST) to a measurement housing (11), hosting said acoustic apparatus (12) and in bi-directional signal connection (16) with said terminal for mobile telecommunications (18), which emits acoustic waves (TW) corresponding to said hearing aid (12) housed in said housing (11), detects acoustic waves (RW) coming out of the hearing aid (12) and supplies the corresponding response signal (SA) of the hearing aid (12) on said bidirectional connection (16) to said mobile telecommunications terminal (18). 11. Process according to claim 10, characterized by sending information on the operating state of the acoustic apparatus (12) based on said values (AS, AT) of said response signal (SA) through said mobile network (22) to a remote control panel (19). Method according to claim 10 or 11 characterized by storing (122) values (AS, AT) of said response signal (SA), in particular in a database (18a) in said mobile telecommunications terminal (18) , acquired in a first initialization phase (100) of the system (10) and to compare (220) values (AS) of said response signal (SA) acquired in a test phase (200) with said stored values (AS) to evaluate information on the operating status of the hearing system (12). CLAIMS 1. System for the diagnosis of the state of operation of a hearing aid (12), comprising means for analyzing the frequency response (AS, AT) of said hearing aid (12) relative to a test signal (ST), characterized in that said means for analyzing the frequency response (AS, AT) comprise a terminal for mobile telecommunications (18) capable of communicating through a mobile communications network (22) and configured to generate a test signal (ST) having variable frequency (f1… fn) and to acquire a response signal (SA) to said test signal (ST) having variable frequency (f1 ... fn), a measurement housing (11) configured to accommodate said acoustic apparatus (12) and in a bidirectional signal link (16) with said terminal for mobile telecommunications (18) and comprising a receiver (13) configured to receive said test signal (ST) from said terminal for mobile telecommunications (18) of said bi-directional signal link (16) and to emit corresponding acoustic wave (TW) towards said hearing aid (12) housed in said measurement housing (11), a microphone (14) for detecting acoustic waves (RW) correspondingly emitted at the output from the hearing aid (12) and providing the response signal (SA) of the hearing aid (12) on said bi-directional link (16) to said terminal for mobile telecommunications (18). 2. System according to claim 1, characterized in that said terminal for mobile telecommunications (18) comprises means for storing values (AS, AT) of said response signal (SA), in particular a database (18a) comprised in said terminal for mobile telecommunications (18). 3. System according to claim 1 or 2, characterized in that said terminal for mobile telecommunications (18) is configured to send information on the state of operation of the hearing aid (12) based on said values (AS, AT) of said response signal (SA) through said mobile network (22) to a remote center (19). 4 System according to claim 3, characterized in that said terminal for mobile telecommunications (18) is configured to send to the remote center (19) data (AS, AT, NS, NT) measured on the hearing aid (12) through said measuring housing (11). 5. System according to claim 3 or 4, characterized in that said terminal for mobile telecommunications (18) is configured to send to the remote center (19) a diagnosis on the component of the hearing aid (12) subject to failure. 6. System according to any of claims from 3 to 5, characterized in that said terminal for mobile telecommunications (18) is configured to send to the remote center (19) a text and / or graphics signalling representative of the test result. 7. System according to any of claims from 1 to 6, characterized in that said mesurement housing (11) comprises means to minimize acoustic losses, in particular a silicone plug (20) configured to wrap at least a portion of the acoustic output of the apparatus (12). 8. System according to any of claims from 1 to 7, characterized in that said bi-directional link (16) is obtained via a cable with four pin audio jack. 9. Kit comprising a mobile terminal (18) and measurement housing (11) configured to operate in the system according to any of claims 1 to 8. 10. A method for diagnosing the state of operation of a hearing aid (12), which includes analyzing the frequency response (AS, AT) of said hearing aid (12) relative to a test signal (ST), characterized by analyzing the frequency response (AS, AT) through the generation of a test signal (ST) having variable frequency having variable frequency (f1… fn) and acquiring a corresponding response signal (SA) via a terminal for mobile telecommunications (18) adapted to communicate on a mobile telecommunications network of (22), sending said test signal (ST) to a measurement housing (11), accommodating said hearing aid (12) and in a bidirectional signal link (16) with said terminal for mobile telecommunications (18), which emits corresponding acoustic waves (TW) toward said hearing aid (12) accommodated in said housing (11), detects acoustic waves (RW) at the output of the hearing instrument (12) and provides the corresponding response signal (SA) of the hearing aid (12) on said bidirectional link (16) to said terminal for mobile telecommunications (18). 11. Method according to claim 10, characterized by sending information on the state of operation of the hearing aid (12) based on said values (AS, AT) of said response signal (SA) through said mobile network (22) to a remote center (19). 12. Method according to claim 10 or 11, characterized by storing (122) values (AS, AT) of said response signal (SA), in particular in a database (18a) in said terminal for mobile telecommunications (18), acquired in a first initialization phase (100) of the system (10) and comparing (220) values (AS) of said response signal (SA) acquired in a test phase (200) with said stored values (AS) to evaluate the information on the state of operation of the hearing aid (12).